This is the Ethernet version of the bMCA-USB. Using an Ethernet connection instead of USB allows installing the device in remote places. Data transfer rates are also tremendously improved.
bMCA is a compact, digital Multi-Channel Analyzer (MCA), which is able to perform Pulse Height Analysis (PHA) of the signal produced by a standard 14-pin standard photomultiplier coupled to a scintillation detector such as NaI(Tl), LaBr3(Ce), LaCl3(Ce), CeBr3, etc.
The device is therefore useful for obtaining the energy spectrum from the photon radiation detected by the scintillator, and can be connected into the local network via a standard Ethernet connection. The device is powered via Ethernet using Power-over-Ethernet (PoE) technology.
The bMCA is provided with a basic software package that allows one to control the device, and to acquire and visualize the energy spectrum. The software incorporates an advanced and easy to use “discovery” function that can be used to detect automatically all the bMCAs (USB or Ethernet) in the neighborhood of the PC that are available for connection. A set of programming libraries are also offered, which makes the incorporation of the bMCA into existing radiation system or setup very easy. The programming libraries are available for both MS Windows and Linux operating systems.
- Fully digital Multi-Channel Analyzer (MCA) built into a compact 14-pin photomultiplier tube base
- Full Pulse-Height Analysis (PHA) and MultiChannel Scaling (MCS) modes of data acquisition
- Up to 4096 channels for PHA and MCS acquisition
- Advanced electronic noise reduction algorithms
- Compact MCA with size of H 75 mm x D 55 mm
- Ethernet data communications with device IP address set via DHCP or fixed
- Extremely fast data communication rates with 1K PHA spectrum being sent to the PC in 30 microseconds
- Miniature design combining low-power consumption with low noise
- Basic spectrum acquisition and device control software included
- Available programming libraries for Windows and Linux Operating System (upon request).
- LED indicators for communication status and device power, HV power and incoming count rate (ICR)
The bMCA is an advanced, fully digital, compact MultiChannel Analyzer (MCA). This device is used to process the electronic pulses produced by a photomultiplier that is coupled to a scintillator detector. Such detectors are commonly used in the detection of gamma-ray radiation due to their high detection efficiency, medium energy resolution and relatively low price. This kind of MCA is able to produce an energy spectrum from the radiation events detected by the scintillator, storing it in the device’s memory for further retrieval and analysis by the PC.
The bMCA implements two modes of data acquisition:
- Pulse Height Analysis (PHA)
- Multi-channel scaling (MCS)
PHA mode is regularly used in nuclear spectrometry and radiometry, while MCS is a very useful feature for following photon detections in specific energy regions as a function of time. MCS acquisition mode is useful in both laboratory and industrial applications that make use of radioactive sources or when seeking for radioactive materials.
Moreover, the MCA has built-in advanced PHA data acquisition modes, such as:
- Acquisition to a number of counts in a spectrum region (ROI)
- The combination of time (live or real) or counts on ROI.
The bMCA design makes use of the latest advances in digital electronics. The MCA utilizes powerful digital processing techniques and algorithms to better separate the useful signal from noise and to maximize performance under high count rate conditions. The acquired spectra under PHA mode is extended for Dead Time. The device has a spectral memory size of up to 4096 channels and can perform MCS in addition to PHA.
The MCA contains a miniaturized high-voltage power supply optimized for low consumption that provides the necessary power for the PMT tube, including those used with large scintillator detectors.
The bMCA has a spectral memory size of up to 4096 channels and can perform MCS in addition to PHA. On the data communications side, this device features lighting-fast transfer rates, with a 1024-channel spectrum being trans-mitted typically in less than 30 microseconds.
A basic acquisition software package is provided for managing such device operations as setup, control, data acquisition and visualization. A digital oscilloscope function allows monitoring the input and filtered pulses to aid in fine tuning the MCA parameters. The program also includes a few spectrometry related functions for processing the spectral data: calibration, ROI analysis and peak search, to mention a few.